CN113223741A

CN113223741A - Radiopharmaceutical leaking needle shielding gloves

Info

Publication number: CN113223741A
Application number: CN202110449447.7A
Authority: CN
Inventors: 陈援浩; 肖苏; 明慧; 刘杨保; 吴继权
Original assignee: Edong Healthcare Group City Central Hospital
Current assignee: Edong Healthcare Group City Central Hospital
Priority date: 2021-04-25
Filing date: 2021-04-25
Publication date: 2021-08-06

Abstract

The invention relates to the technical field of labor protection supplies, in particular to a radiopharmaceutical missed stitch shielding glove which comprises a finger part, a palm part, an arm part and a lead shielding interlayer, wherein the finger part, the palm part and the arm part are mutually communicated, the finger part is fixedly connected to one end of the palm part, the arm part is fixedly connected to the other end of the palm part, the lead shielding interlayer is slidably sleeved on the outer side of the arm part, the lead shielding interlayer can slide back and forth on the outer surface of the arm part, the lead shielding interlayer is of an annular structure, an elastic band is fixedly connected to the outer ring of the lead shielding interlayer, and an adhesive is fixedly connected to the outer ring of the lead shielding interlayer. The radiopharmaceutical leaking needle shielding glove can solve the problem that the leaked radiopharmaceutical causes great interference to an imaging image after the radiopharmaceutical leaks out of a blood tube and during later imaging due to misoperation or self reasons of patients such as obesity, thin blood vessels, blood vessel variation and the like during radiopharmaceutical injection.

Description

Radiopharmaceutical leaking needle shielding gloves

Technical Field

The invention relates to the technical field of labor protection articles, in particular to a radiopharmaceutical miss-stitch shielding glove.

Background

In nuclear medicine diagnosis, most radiopharmaceuticals are used, generally, medical staff need to inject the radiopharmaceuticals into blood vessels of patients, but due to misoperation or self reasons of obesity, blood vessel fineness, blood vessel variation and the like of the patients, the radiopharmaceuticals leak out of the blood vessels, so that when imaging is carried out at a later stage, the leaked radiopharmaceuticals cause great interference on imaging images, the quality of the images is influenced, the patients cannot understand the images, and interpretation of imaging doctors or artificial intelligence on the images is influenced.

At present, for the condition of the missed needle of the radioactive medicine, the solution is to train the personnel injecting the medicine, improve the skill and reduce the missed needle rate on one hand, and on the other hand, the technicians manually remove the missed part through software when processing images at the later stage. The existing patent is mostly radiation-proof gloves for medical staff, and the drop-stitch shielding gloves for patients are not used.

However, the level of the people who inject the medicine is uneven, the self condition of the patient is unchangeable, and the condition of missed injection cannot be avoided after training; the local images are removed in the later period, so that the whole image is influenced. The existing specialization is mostly radiation-proof gloves used for medical staff, and the missed stitch shielding gloves for patients are not available.

Disclosure of Invention

The invention aims to solve the defects that the existing radiation-proof gloves are mostly used for medical staff and do not have the leakage needle shielding gloves of patients in the prior art, and provides the radiopharmaceutical leakage needle shielding gloves.

In order to achieve the purpose, the invention adopts the following technical scheme:

the design is a radiopharmaceutical leaking needle shielding glove, including finger portion, palm portion, arm and plumbous system shielding interlayer, finger portion palm portion and communicate each other between the arm three, finger portion fixed connection is in the one end of palm portion, arm fixed connection is in the other end of palm portion, plumbous system shielding interlayer sliding sleeve is established the outside of arm, plumbous system shielding interlayer can make a round trip to slide on the surface of arm, plumbous system shielding interlayer is the loop configuration, the outer lane fixedly connected with elastic cord of plumbous system shielding interlayer, the outer lane fixedly connected with of plumbous system shielding interlayer pastes, just the elastic cord with paste mutual adaptation between.

Preferably, the inner surface of the arm part is fixedly connected with a protective layer, and the protective layer is of an annular structure.

Preferably, the protective layer comprises a buffer layer, a warm-keeping layer and a breathable layer, the buffer layer, the warm-keeping layer and the breathable layer are all of an annular structure, the outer ring of the buffer layer is fixedly connected to the inner surface of the arm part, the outer ring of the warm-keeping layer is fixedly connected to the inner ring of the buffer layer, and the outer ring of the breathable layer is fixedly connected to the inner ring of the warm-keeping layer.

Preferably, the inner ring of the breathable layer is fixedly connected with a contact layer.

Preferably, the buffer layer comprises a first elastic material layer and a second elastic material layer, the first elastic material layer and the second elastic material layer are both of annular structures, an outer ring of the first elastic material layer is fixedly connected to the inner surface of the arm part, an outer ring of the second elastic material layer is fixedly connected to an inner ring of the first elastic material layer, and the inner ring of the second elastic material layer is fixedly connected to an outer ring of the warm-keeping layer.

Preferably, the warm-keeping layer comprises a first heat-preservation material layer and a second heat-preservation material layer, the first heat-preservation material layer and the second heat-preservation material layer are both of annular structures, an outer ring of the first heat-preservation material layer is fixedly connected to the inner ring of the buffer layer, an outer ring of the second heat-preservation material layer is fixedly connected to the inner ring of the first heat-preservation material layer, and the inner ring of the second heat-preservation material layer is fixedly connected to the outer ring of the breathable layer.

Preferably, the length of the arm part is 20-28 cm.

Preferably, the lead shielding interlayer has a width of 4-5 cm, a thickness of 0.8-1.2 mm, and a lead equivalent of 0.30-0.45 mmpb.

The radiopharmaceutical miss-stitch shielding glove provided by the invention has the beneficial effects that: this radiopharmaceutical miss needle shielding gloves passes through the setting of plumbous system shielding interlayer, elastic cord and pasting, and plumbous system shielding interlayer can slide from top to bottom along with the arm, and when the radiopharmaceutical spills from the blood vessel, this plumbous system shielding interlayer slides to here promptly to according to the arm size, the adjustment elastic cord makes annular plumbous system shielding interlayer more firm, so that shield the radiopharmaceutical that this position spills, improve the formation of image. Therefore, the invention can embody the humanistic care of the medical staff to the patient and is convenient to operate; the method can solve the problem that the leaked radiopharmaceuticals cause great interference to imaging images after the radiopharmaceuticals leak out of the blood vessels due to misoperation or self reasons of patients with obesity, thin blood vessels, blood vessel variation and the like during radiopharmaceutical injection and during later imaging.

Drawings

Fig. 1 is a schematic structural view of a radiopharmaceutical drop stitch shielding glove provided by the invention.

Fig. 2 is a structural side view of the arm part of a radiopharmaceutical drop-stitch shielding glove according to the present invention.

Fig. 3 is a schematic structural diagram of the protective layer in fig. 2.

In the figure: the finger part 1, the palm part 2, the arm part 3, the lead shielding interlayer 4, the elastic band 5, the adhesive 6, the protective layer 7, the buffer layer 71, the first elastic material layer 711, the second elastic material layer 712, the heat preservation layer 72, the first heat preservation material layer 721, the second heat preservation material layer 722, the breathable layer 73 and the contact layer 74.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Example 1

Referring to fig. 1-3, a radiopharmaceutical miss-stitch shielding glove comprises a finger part 1, a palm part 2, an arm part 3 and a lead shielding interlayer 4, wherein the finger part 1, the palm part 2 and the arm part 3 are communicated with each other, the finger part 1 is fixedly connected to one end of the palm part 2, the arm part 3 is fixedly connected to the other end of the palm part 2, the arm part 3 is 20-28cm long, and the finger part 1, the palm part 2 and the arm part 3 are all made of vulcanized rubber materials.

The lead shielding interlayer 4 is sleeved on the outer side of the arm part 3 in a sliding mode, the lead shielding interlayer 4 can slide back and forth on the outer surface of the arm part 3, the lead shielding interlayer 4 is of an annular structure, the width of the lead shielding interlayer 4 is 4-5 cm, the thickness of the lead shielding interlayer 4 is 0.8-1.2 mm, the lead equivalent is 0.30-0.45mmpb, and the lead shielding interlayer 4 is made of lead materials.

Lead system shielding interlayer 4's outer lane fixedly connected with elastic cord 5, lead system shielding interlayer 4's outer lane fixedly connected with pastes 6, and elastic cord 5 and paste mutual adaptation between 6, elastic cord 5 and the edge of pasting 6 fixed connection at lead system shielding interlayer 4, lead system shielding interlayer 4 can slide from top to bottom along with the arm, when the radiopharmaceutical spills from the blood vessel, this lead system shielding interlayer 4 slides to here promptly, and according to the arm size, adjustment elastic cord 5, it is more firm to make annular lead system shielding interlayer 4, so that shield the radiopharmaceutical that this position spilt, improve into image. Therefore, the invention can embody the humanistic care of the medical staff to the patient and is convenient to operate; the method can solve the problem that the leaked radiopharmaceuticals cause great interference to imaging images after the radiopharmaceuticals leak out of the blood vessels due to misoperation or self reasons of patients with obesity, thin blood vessels, blood vessel variation and the like during radiopharmaceutical injection and during later imaging.

Example 2

Referring to fig. 2-3, as another preferred embodiment of the present invention, the difference from embodiment 1 is that the inner surface of the arm portion 3 is fixedly connected with the protective layer 7, the protective layer 7 is of an annular structure, the protective layer 7 includes a buffer layer 71, a thermal insulation layer 72 and a ventilation layer 73, the buffer layer 71, the thermal insulation layer 72 and the ventilation layer 73 are all of an annular structure, an outer ring of the buffer layer 71 is fixedly connected to the inner surface of the arm portion 3, an outer ring of the thermal insulation layer 72 is fixedly connected to an inner ring of the buffer layer 71, an outer ring of the ventilation layer 73 is fixedly connected to an inner ring of the thermal insulation layer 72, and an inner ring of the ventilation layer 73 is fixedly connected with a contact layer 74, through the arrangement of the buffer layer 71, the thermal insulation layer 72 and the ventilation layer 73, the inner surface of the arm portion 3 can have a buffer function, a thermal insulation function and a ventilation function, and under the effect of the buffer layer 71, when a patient wears the glove, the glove can have a certain buffer acting force, thereby having good buffering and protecting effects on the arms of the patient; under the action of the warm-keeping layer 72, the warm-keeping effect of the glove can be ensured, so that the glove is beneficial to better arm blood circulation when a patient wears the glove; the breathable properties of the glove are thus enhanced by the breathable layer 73, which makes the glove more comfortable for the patient to wear.

Buffer layer 71 includes first elastic material layer 711 and second elastic material layer 712, first elastic material layer 711 and second elastic material layer 712 are the loop configuration, first elastic material layer 711 outer lane fixed connection is at the 3 internal surfaces of arm portion, second elastic material layer 712 outer lane fixed connection is at first elastic material layer 711 inner circle, and be fixed connection between second elastic material layer 712 inner circle and cold-proof layer 72 outer lane, through first elastic material layer 711 and second elastic material layer 712, when the patient wore this gloves, can have certain buffering effort, thereby can play the fine buffering protection effect to patient's arm.

The thermal layer 72 comprises a first thermal insulation material layer 721 and a second thermal insulation material layer 722, the first thermal insulation material layer 721 and the second thermal insulation material layer 722 are both in an annular structure, the outer ring of the first thermal insulation material layer 721 is fixedly connected to the inner ring of the buffer layer 71, the outer ring of the second thermal insulation material layer 722 is fixedly connected to the inner ring of the first thermal insulation material layer 721, the outer ring of the second thermal insulation material layer 722 is fixedly connected to the outer ring of the breathable layer 73, and the thermal insulation effect of the glove can be ensured by arranging the first thermal insulation material layer 721 and the second thermal insulation material layer 722, so that the blood circulation of the arm is better when the patient wears the glove.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides a radiopharmaceutical leaking needle shielding gloves, includes finger portion (1), palm portion (2), arm portion (3) and plumbous system shielding interlayer (4), its characterized in that, finger portion (1), palm portion (2) and communicate each other between arm portion (3) the three, finger portion (1) fixed connection in the one end of palm portion (2), arm portion (3) fixed connection in the other end of palm portion (2), plumbous system shielding interlayer (4) slip cap is established in the outside of arm portion (3), plumbous system shielding interlayer (4) can make a round trip to slide on the surface of arm portion (3), plumbous system shielding interlayer (4) are the loop configuration, the outer lane fixedly connected with elastic cord (5) of plumbous system shielding interlayer (4), the outer lane fixedly connected with of plumbous system shielding interlayer (4) pastes (6), and the elastic band (5) and the paste (6) are mutually matched.

2. A radiopharmaceutical drop needle shielding glove as set forth in claim 1, wherein a protective layer (7) is fixedly attached to an inner surface of the arm portion (3), and the protective layer (7) has a ring-shaped structure.

3. The radiopharmaceutical miss shielding glove according to claim 2, wherein the protective layer (7) comprises a buffer layer (71), a thermal insulation layer (72) and a ventilation layer (73), the buffer layer (71), the thermal insulation layer (72) and the ventilation layer (73) are all of annular structures, an outer ring of the buffer layer (71) is fixedly connected to the inner surface of the arm part (3), an outer ring of the thermal insulation layer (72) is fixedly connected to an inner ring of the buffer layer (71), and an outer ring of the ventilation layer (73) is fixedly connected to an inner ring of the thermal insulation layer (72).

4. A radiopharmaceutical leaking needle shielding glove according to claim 3, wherein the inner ring of the air permeable layer (73) is fixedly connected with a contact layer (74).

5. The radiopharmaceutical miss shielding glove of claim 3, wherein the buffer layer (71) comprises a first elastic material layer (711) and a second elastic material layer (712), the first elastic material layer (711) and the second elastic material layer (712) are both in an annular structure, an outer ring of the first elastic material layer (711) is fixedly connected to the inner surface of the arm part (3), an outer ring of the second elastic material layer (712) is fixedly connected to an inner ring of the first elastic material layer (711), and the inner ring of the second elastic material layer (712) is fixedly connected to an outer ring of the warming layer (72).

6. The radiopharmaceutical miss shielding glove of claim 3, wherein the thermal insulation layer (72) comprises a first thermal insulation material layer (721) and a second thermal insulation material layer (722), the first thermal insulation material layer (721) and the second thermal insulation material layer (722) are both in an annular structure, the outer ring of the first thermal insulation material layer (721) is fixedly connected to the inner ring of the buffer layer (71), the outer ring of the second thermal insulation material layer (722) is fixedly connected to the inner ring of the first thermal insulation material layer (721), and the inner ring of the second thermal insulation material layer (722) is fixedly connected to the outer ring of the air-permeable layer (73).

7. A radiopharmaceutical miss shielding glove according to claim 3, characterised in that the length of the arm portion (3) is 20-28 cm.

8. A radiopharmaceutical leaking needle shielding glove according to claim 3, characterized in that the lead shielding layer (4) has a width of 4-5 cm, a thickness of 0.8-1.2 mm and a lead equivalent of 0.30-0.45 mmpb.